1. ANNEX 4
WHO RECOMMENDATIONS FOR
THE PRODUCTION, CONTROL AND REGULATION OF
HUMAN PLASMA FOR FRACTIONATION
Adopted by the 56th meeting of the WHO Expert Committee on Biological Standardization, 24-28
October 2005. A definitive version of this document, which will differ from this version in editorial
but not scientific detail, will be published in the WHO Technical Report Series.
2. Page 2
TABLE OF CONTENTS
Page
TABLE OF CONTENTS.................................................................................................................
INTRODUCTION ............................................................................................................................
1 INTERNATIONAL BIOLOGICAL REFERENCE PREPARATIONS ............................
2 LIST OF ABBREVIATIONS AND DEFINITION USED ...................................................
3 GENERAL CONSIDERATIONS...........................................................................................
3.1 Range of products made from human blood and plasma .......................................................
3.2 Composition of human plasma...............................................................................................
3.3 Pathogens present in blood and plasma..................................................................................
4 MEASURES TO EXCLUDE INFECTIOUS DONATIONS ...............................................
4.1 Appropriate selection of blood/plasma donors.......................................................................
4.2 Screening of blood/plasma donations for infectious markers ................................................
4.2.1 Screening tests .............................................................................................................
4.2.2 Other tests....................................................................................................................
4.2.3 NAT testing .................................................................................................................
4.2.4 Test kits .......................................................................................................................
4.2.5 Quality control of screening ........................................................................................
4.2.6 Look- back...................................................................................................................
4.3 Epidemiological surveillance of donor population ................................................................
4.4 Strict adherence to Good Manufacturing Practices ................................................................
4.5 Post donation events...............................................................................................................
5 PRODUCTION OF PLASMA FOR FRACTIONATION ...................................................
5.1 Methods used to obtain plasma for fractionation ...................................................................
5.1.1 Recovered plasma........................................................................................................
5.1.2 Apheresis plasma (source plasma) ..............................................................................
5.2 Characteristics of plasma for fractionation ............................................................................
5.2.1 Plasma frozen within 24 hours of collection ...............................................................
5.2.2 Plasma frozen after 24 hours of collection ..................................................................
5.2.3 Plasma not meeting the requirement for fractionation ................................................
5.2.4 Hyper-immune (antibody-specific) plasma.................................................................
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5.2.4.1 Anti-D (anti-Rho) ..............................................................................................
5.2.4.2 Anti-HAV..........................................................................................................
5.2.4.3 Anti-HBs ...........................................................................................................
5.2.4.4 Anti-tetanus .......................................................................................................
5.2.4.5 Anti-varicella/zoster ..........................................................................................
5.2.4.6 Anti-cytomegalovirus........................................................................................
5.2.4.7 Anti-rabies .........................................................................................................
5.3 Premises and devices for collection of plasma for fractionation............................................
5.3.1 Premises.......................................................................................................................
5.3.2 Containers....................................................................................................................
5.3.3 Anticoagulants.............................................................................................................
5.4 Blood/plasma collection process ............................................................................................
5.4.1 Procedure.....................................................................................................................
5.4.2 Labelling of collection bags ........................................................................................
5.4.3 Equipment....................................................................................................................
5.4.4 Laboratory samples .....................................................................................................
5.4.5 Volume of plasma per unit ..........................................................................................
5.4.6 Secure holding and reconciliation ...............................................................................
5.4.7 Donor call back system ...............................................................................................
5.5 Separation of plasma ..............................................................................................................
5.5.1 Premises.......................................................................................................................
5.5.2 Intermediate storage and transport ..............................................................................
5.5.3 Impact of whole blood holding period ........................................................................
5.5.4 Centrifugation of whole blood.....................................................................................
5.5.5 Impact of leucoreduction.............................................................................................
5.6 Freezing of plasma .................................................................................................................
5.6.1 Holding time of plasma ...............................................................................................
5.6.2 Freezing rate and freezing temperature .......................................................................
5.6.2.1 Freezing conditions ...........................................................................................
5.6.2.2 Impact of containers and equipment .................................................................
5.6.2.3 Validation of the freezing process.....................................................................
5.7 Storage of plasma ...................................................................................................................
5.7.1 Storage conditions and validation ...............................................................................
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5.7.2 Premises and equipment ..............................................................................................
5.7.3 Segregation procedures ...............................................................................................
5.8 Compliance with plasma fractionator equipment...................................................................
5.9 Release of plasma for fractionation........................................................................................
5.9.1 Plasma release using electronic information systems .................................................
5.10 Packaging of plasma...............................................................................................................
5.11 Transportation of plasma........................................................................................................
5.12 Recall system..........................................................................................................................
6 QA SYSTEM AND GOOD MANUFACTURING PRACTICES........................................
6.1 Organisation and personnel ....................................................................................................
6.2 Documentation system ...........................................................................................................
6.3 Premises and equipment.........................................................................................................
6.4 Materials.................................................................................................................................
6.5 Validation programme............................................................................................................
6.6 Quality monitoring data..........................................................................................................
6.7 Virology safety testing ...........................................................................................................
6.7.1 Sampling......................................................................................................................
6.7.2 Test equipment ............................................................................................................
6.7.3 Assay performance validation .....................................................................................
6.7.4 Test interpretation and downloading ...........................................................................
6.7.5 Follow-up of reactives.................................................................................................
6.8 Electronic information system................................................................................................
6.9 Storage and transport..............................................................................................................
6.10 Change control system ...........................................................................................................
6.11 QA auditing ............................................................................................................................
6.12 Defect reporting system..........................................................................................................
6.13 Quality agreement between blood establishment and fractionator ........................................
6.14 Blood/plasma establishment audit and inspection..................................................................
7 REGULATORY CONTROL OF PLASMA FOR FRACTIONATION.............................
7.1 Role of national regulatory authority .....................................................................................
7.2 Establishment license and inspections ...................................................................................
7.3 Impact of GMP.......................................................................................................................
7.4 Inspections..............................................................................................................................
5. Page 5
8 AUTHORS ................................................................................................................................
9 Annex 1: plasma products and clinical applications (adapted from [6]..............................
10 Annex 2: donor selection..........................................................................................................
10.1 Preamble.................................................................................................................................
10.2 Information to donors.............................................................................................................
10.3 Compliance with donor selection criteria...............................................................................
10.3.1 Positive identification of donors..................................................................................
10.3.2 Confidentiality.............................................................................................................
10.3.3 Questionnaire and interview........................................................................................
10.3.4 Physical examination, Acceptance and deferral criteria..............................................
10.3.4.1 Physical exam....................................................................................................
10.3.4.2 Records and traceability ....................................................................................
10.3.4.3 Selection and exclusion criteria.........................................................................
10.3.4.4 Reinstatement ....................................................................................................
10.3.4.5 Procedures .........................................................................................................
11 Annex 3: Donor immunization and plasmapheresis for specific immunoglobulins...........
12 Annex 4: Contract plasma fractionation program................................................................
13 Annex 5: Technical points to consider in establishing plasma specifications criteria
and obligations between blood establishment and plasma fractionator .............................
14 REFERENCES .........................................................................................................................
6. Page 6
INTRODUCTION
Human plasma is a source of important medicinal products which are obtained by a combination of
large-scale processing steps called “fractionation”. It is important that these products have an appropriate
quality and safety profile.
Recognizing the importance of the provision of safe blood, blood components and plasma
derivatives, the 58th World Health Assembly in 2005 (WHA Resolution 58.13) [1] supports "the full
implementation of well-organized, nationally coordinated and sustainable blood programmes with
appropriate regulatory systems" and stresses the role of "voluntary, non-remunerated blood donors from
low-risk populations". The provision of blood, blood components and plasma derivatives from voluntary,
non remunerated donors should be the aim of all countries.
The WHO requirements for the collection, processing, and quality control of blood, blood
components, and plasma derivatives were published in 1994 [2]. Numerous developments have taken place
since the time that document was published, requiring that updated both technical and regulation guidelines
be prepared and made public at global level. The recently published WHO guidelines on viral inactivation
and removal procedures [3] address the measures necessary to eliminate or reduce the risk from blood-borne
viruses during processing of plasma into plasma derivatives.
The present Recommendations are intended to provide guidance on the production, control and
regulation of human plasma for fractionation as a source material for plasma derived medicinal products.
Such combination of information is necessary for the manufacture of safe plasma derivatives at global level,
in both developed and developing countries.
The current document, by bringing together experience and information, will serve as a guide to
blood establishments in their implementation of appropriate procedures for the production and control of the
starting plasma material, and will facilitate the provision of safe fractionated plasma products at national
level. It is intended to assist National (Medicine) Regulatory Authorities (NRA) in establishing the
supervision necessary for assessment of the quality and safety of plasma for fractionation, either prepared
locally or imported, and will therefore contribute to improved quality and safety of human plasma products
worldwide. Manufacturers of plasma derivatives (fractionators) may use these guidelines when discussing
the quality criteria of plasma for fractionation with representatives of blood establishments and the NRA.
This guidance document addresses only human plasma sourced for the manufacture of plasma
derivatives. Plasma for clinical use is not discussed, nor is there any consideration of plasma from other
species.
1 INTERNATIONAL BIOLOGICAL REFERENCE PREPARATIONS
Rapid technological developments in the measurement of biological activity of blood and blood
products has required and still require the establishment of international biological reference materials. The
full list of current reference materials relevant to blood products and related substances is available at the
following WHO Web site address: http://www.who.int/bloodproducts/ref_materials/
The biological activity of blood products should be measured by comparison with the relevant
International standard. Activity is usually expressed in International Units (IU), but may in some cases be
expressed in SI units.
7. Page 7
2 LIST OF ABBREVIATIONS AND DEFINITION USED
The definitions given below apply to the terms used in these Recommendations. They may have
different meanings in other contexts.
Apheresis: procedure whereby blood is removed from the donor, separated by physical means into
components and one or more of them returned to the donor.
Blood collection: a procedure whereby a single donation of blood is collected in an anticoagulant and/or
stabilizing solution, under conditions designed to minimize microbiological contamination of the resulting
donation.
Blood component: A constituent of blood (red cells, white cells, platelets, plasma) that can be prepared
under such conditions that it can be used directly or after further processing for therapeutic applications.
Blood establishment: Any structure or body that is responsible for any aspect of the collection and testing
of human blood or blood components, whatever their intended purpose, and their processing, storage, and
distribution when intended for transfusion.1
Donor: a person who gives blood or plasma used for fractionation.
EIS: Electronic information system
Factor VIII: Blood coagulation factor VIII, deficient in patients with haemophilia A. Also called
antihaemophilic factor.
Factor IX: Blood coagulation factor IX, deficient in patients with haemophilia B.
First time tested donor: A person whose blood/plasma is tested for the first time for infectious disease
markers in a blood establishment.
Fractionation: (large-scale) process by which plasma is separated into individual protein fractions, that are
further purified for medicinal use (variously referred to as “plasma derivatives”, fractionated plasma
products or plasma-derived medicinal products). The term fractionation is usually used to describe a
sequence of processes, including: plasma protein separation steps (typically precipitation and/or
chromatography), purification steps (typically ion-exchange or affinity chromatography) and one or more
steps for inactivation or removal of blood-borne infectious agents (most specifically viruses and, possibly,
prions).
Fractionator: a company or an organization performing plasma fractionation to manufacture plasma-
derived medicinal products.
FFP: Fresh frozen plasma, used for transfusion
GE: Genome equivalents: The amount of nucleic acid of a particular virus assessed using nucleic acid
testing.
GMP. Good Manufacturing Practice: that part of Quality Assurance which ensures that products are
consistently produced and controlled to the quality standards appropriate to their intended use and as
required by the marketing authorization or product specification. It is concerned with both production and
quality control
HAV, Hepatitis A virus. A non-enveloped, single-stranded RNA virus, causative agent of hepatitis A
HBsAg, Hepatitis B surface antigen. The antigen on the periphery of hepatitis B virus.
HBV, Hepatitis B virus. An enveloped, double-stranded DNA virus, causative agent of hepatitis B.
HCV, Hepatitis C virus. An enveloped, single-stranded, RNA virus, causative agent of hepatitis C.
HEV, Hepatitis E virus. A non-enveloped, single-stranded RNA virus, causative agent of hepatitis E.
HGV, Hepatitis G virus [(or GB virus C (GBV-C)]. An enveloped single-stranded RNA virus, causative
agent of hepatitis G.
HIV. Human immunodeficiency virus. An enveloped, single-stranded RNA virus, causative agent of
AIDS
Incidence: The rate of newly-acquired infection identified over a specified time period in a defined
population.
1
A blood center is a blood establishment
8. Page 8
Inventory hold period: period during which the plasma for fractionation is on hold pending identification
and elimination of possible window-phase donations
IVIG. Intravenous immunoglobulin. Also known as Immune Globulin intravenous.
Lookback: Procedure to be followed if it was found retrospectively that a donation from a high-risk donor
should have been excluded from processing.
Manufacture: all operations of procurement of materials (including collection of plasma for fractionation)
and products, production, quality control, release, storage, distribution, and quality assurance of plasma-
derived medicinal products
NAT: Nucleic acid testing, using amplification techniques such as polymerase chain reaction.
NRA: National Regulatory Authority. WHO terminology to refer to national medicines regulatory
authorities. Such authorities promulgate medicines regulations and enforce them.
Plasma: the liquid portion remaining after separation of the cellular elements from blood collected in a
receptacle containing an anticoagulant, or separated by continuous filtration or centrifugation of
anticoagulated blood in an apheresis procedure.
Plasmapheresis: procedure in which whole blood is removed from the donor, the plasma is separated from
the cellular elements and at least the red blood cells are returned to the donor
Plasma products: A range of medicinal products (as listed in Annex 1) obtained by the fractionation
process of human plasma. Also called plasma derivatives or plasma-derived medicinal products.
Plasma for fractionation: Recovered plasma or source plasma used for the production of plasma products.
Plasma Master File: A document which provides all relevant detailed information on the characteristics of
the entire human plasma used by a fractionator as starting material and/or raw material for the manufacture
of sub/intermediate plasma fractions, constituents of the excipient and active substance(s), which are part of
a medicinal product.
Prevalence: The rate of infection identified, including both past and present infections, at a specified point
in time or over a specified time period in a defined population
Prion: The infectious particle associated with transmissible spongiform encephalopathies. It is believed to
consist only of protein and to contain no nucleic acid.
Production: all operations involved in the preparation of plasma-derived medicinal products, from
collection of blood or plasma, through processing and packaging, to its completion as a finished product.
Recovered plasma: plasma recovered from a whole blood donation and used for fractionation.
Repeat tested donor: A person whose blood/plasma has been tested previously for infectious disease
markers in the blood establishment
Replacement donor: Person who gives blood upon request of a specific patient or patient's family or
acquaintance, which in principle is intended to be used specifically for the treatment of that patient.
SD-Plasma: Solvent/detergent-treated pooled plasma intended as a substitute for FFP.
Serious adverse event: any untoward occurrence associated with the collection, testing, processing, storage
and distribution, of blood and blood components that might lead to death or life-threatening, disabling, or
incapacitating conditions for patients or which results in, or prolongs, hospitalization or morbidity.2
Serious adverse reaction: an unintended response in donor associated with immunization that is fatal, life-
threatening, disabling, incapacitating, or which results in, or prolongs, hospitalization or morbidity. 3
Source plasma: plasma obtained by plasmapheresis for further fractionation into plasma products
Traceability: Ability to trace each individual unit of blood or blood component derived thereof from the
donor to its final destination, whether this is a recipient, one or more batches of medicinal product or
disposal. The term is used to describe forward tracing (donation to disposition) and reverse tracing
(disposition to donation)
TSE: Transmissible spongiform encephalopathy
TTV: TT virus, is a non-enveloped, single-stranded DNA virus, causing post-transfusion hepatitis of
unknown etiology.
2
& 3 relates to the immunization of the donor
9. Page 9
Viral inactivation: A process of enhancing viral safety in which the virus is intentionally “killed”.
Viral removal: A process of enhancing viral safety by removing or separating the virus from the protein(s)
of interest.
WNV: West Nile virus is an enveloped single-stranded RNA virus, causative agent of West Nile fever
3 GENERAL CONSIDERATIONS
3.1 Range of products made from human blood and plasma
A range of products can be made from human blood. Some of these products, generally known as
blood components, include red cell concentrates, platelet concentrates, leucocyte concentrates, and plasma
for transfusion. These components are obtained from the processing of single donations of blood or plasma
but small pools, usually of less than 10 donations, mainly for the production of platelets [4], can also be
prepared by blood establishments4. The safety of these blood components depends largely on the selection
criteria of the donors and the screening of the donations.
Other blood products are obtained by the industrial processing of plasma of a large number of
donations (up to tens of thousands) that are pooled together. These products include pooled virally-
inactivated plasma for transfusion that is not fractionated, and the purified plasma products, also known as
plasma derivatives, that are obtained by a fractionation process that combines protein purification and viral
inactivation and removal steps.
Table 1 summarizes the range of products made from human blood and plasma, illustrating the
diversity of source material and manufacturing methods involved, and, consequently, the complex
regulation needed to ensure their quality and safety, in particular with regards to the control of infectious
risks.
Plasma derived products are regarded as medicinal products worldwide and their marketing
authorization, which involves the official approval of the production process and quality assurance system
used as well as of product efficacy, should be under the responsibility of the NRA in all Member States.
The NRA has the duty to enforce regulations, to evaluate quality and safety of products, and to conduct
regular assessment and inspection of the manufacturing sites.
An important part in the evaluation of the marketing authorization of plasma products relates to the
production and control of the starting plasma used for fractionation, and is the focus of this Guideline.
4
Small-pool cryoprecipitate is produced in some countries
10. Page 10
Table 1: Range of blood / plasma products derived from single donor or pooled donations
SINGLE-DONOR BLOOD COMPONENTS
Whole Blood
Red cell concentrate
Platelet concentrate (obtained by apheresis)
Leucocyte concentrate
Plasma for transfusion
Cryoprecipitate
Cryo-poor plasma
SMALL POOL BLOOD COMPONENTS
Platelet concentrates (obtained from whole blood)5
Cryoprecipitate6
LARGE POOL, UNFRACTIONATED VIRALLY INACTIVATED PLASMA PRODUCT
Plasma for transfusion, Solvent-detergent (SD) treated [5]
LARGE POOL PRODUCTS PURIFIED BY FRACTIONATION OF PLASMA
See the list of products in Annex 1
3.2 Composition of human plasma
Human plasma is a complex biological material composed of hundreds of biochemical
entities, some of which have not yet been fully characterized. Among these are albumin, various
classes of immunoglobulins, coagulation factors, anticoagulants, protease inhibitors, and growth
factors. The complexity of plasma is illustrated in the Table 2.
Concentrations of the various protein components vary from about 40g/litre (albumin)
down to a few nanograms/ml for some coagulation factors. Plasma protein molecular mass varies
from several million daltons (the von Willebrand multimer complex) to tens of thousands Daltons
(for example Albumin).
Human Plasma for Fractionation is the starting material for manufacture of a range of
medicinal products used for the treatment of a variety of life-threatening injuries and diseases. A
list which includes the most established clinical use of these products is provided in Annex 2.
5
Usually 4 to 10 platelet concentrates derived either from platelet-rich-plasma or from buffy coats.
6
Rarely produced. Pooled cryoprecipitate should ideally be subjected to a viral inactivation treatment. Also
used as a fibrinogen source for fibrin sealant (fibrin glue)
11. Page 11
Table 2: Selected Proteins of Human Plasma (adapted from [6, 7])
MAJOR PROTEINS
Daltons mg/Litre
• Albumin 68 000 40 000
• IgG 150 000 12 500
PROTEASE INHIBITORS
• Alpha 2 macroglobulin 815 000 2 600
• Alpha 1 antitrypsin 52 000 1 500
• C1-esterase inhibitor 104 000 170
• Antithrombin 58 000 100
• Heparin cofactor II 65 000 100
• Alpha 2 -antiplasmin 69 000 70
PROTEASE
ADAMTS13 190 1
FIBRINOLYTIC PROTEINS
• Plasminogen 92 000 200
• Histidine-rich glycoprotein 75 000 100
COAGULATION FACTORS and ANTI-COAGULANT PROTEINS
• Fibrinogen 340 000 3 000
• Fibronectin 250 000 300
• Prothrombin 72 000 150
• Factor XIII 320 000 30
• Protein S 69 000 29
• Von Willebrand Factor (monomer) 220 000 10
• Factor II 7 72 000 150
• Factor X 59 000 10
• Factor V 286 000 7
• Factor XI 80 000 5
• Factor IX 57 000 5
• Factor XII 76 000 40
• Protein C 57 000 4
• Factor VII 50 000 0.5
• Factor VIII 330 000 0.3
CYTOKINES8
• IL-2 15 000 Traces
• G-CSF 20 000 < 30 pg/ml
• Erythropoietin 34 000 0.3 microg/Litre
7
Factor II is the zymogen plasma protein which upon activation generates thrombin, one of the components
of fibrin sealant (fibrin glue).
8
There are several cytokines present in traces in plasma. G-CSF and erythropoietin for therapeutic use are
obtained by recombinant technology
12. Page 12
3.3 Pathogens present in blood and plasma
A number of infectious agents can be present in human blood but not all blood-borne
pathogens can be transmitted by plasma for transfusion or plasma derivatives [8]. Some pathogens
are exclusively associated with blood cells, or are at least partially sensitive to the freeze-thaw
process that takes place during the manufacture of plasma and plasma products. In addition, the
multiple sterilizing filtration steps systematically included in the manufacture of plasma products,
as for any other parenteral preparation, eliminate micro-organisms larger than 0.2µm.
Table 3 summarizes the major infectious risks linked to blood-borne pathogens and presents the
current evidence of risks of infection from cellular components, plasma and fractionated plasma
products.
Some of the viruses listed in the Table are highly pathogenic (e.g. HIV, HCV, HBV), others
are pathogenic only in certain recipient populations (e.g. CMV, B19) and few are currently
considered to be non-pathogenic (HGV, TTV).
Historically, clinical use of single-donor blood components and pooled plasma products
(plasma derivatives) has been associated with transmission of blood-borne viruses (HBV, HCV,
HIV, HAV and B19) [3]. The implementation of validated virus inactivation and removal steps into
the manufacturing process of plasma derivatives has now virtually eliminated the risks of infection
from HIV, HBV, and HCV [3] and also avoided the transmission of some emerging infectious
agents, such as WNV [9, 10].
The infective agents for the bacterial and parasitic infections most commonly associated
with transfusions of cellular blood components are reliably removed, as are residual blood cells,
during the processing and aseptic filtration of plasma products.
13. Page 13
Table 3: EVIDENCE OF TRANSMISSION OF INFECTIOUS AGENTS BY HUMAN BLOOD 9
CELLULAR PLASMA
INFECTIOUS AGENTS BLOOD PLASMA PRODUCTS
COMPONENTS
VIRUSES
HIV I & II + + +
HBV + + +
HCV + + +
Hepatitis Delta virus + + +
HAV + + +
HEV + + +
HGV + + +
TT virus + + +
Parvovirus B19 + + +
Human T-cell leukemia virus I & II + - -
Cytomegalovirus + - -
Epstein Barr virus + - -
West Nile virus + ? -
Dengue virus + ? -
Human Herpes virus-8 ? - -
10
Simian foamy virus ? ? -
Severe Acute Respiratory Syndrome virus ?11 ? -
BACTERIA
Spirochete (syphilis) + - -
Parasites
Babesia microti + - -
Plasmodium (Malaria) + - -
Leishmania (Leishmaniosis) + - -
Trypanosoma cruzi (Chagas Disease) + - -
UNCONVENTIONAL AGENTS /TSE
Creutzfeldt Jakob Disease agent - - -
Variant Creutzfeld Jakob Disease agent + ? -12
+: evidence of transmission; -: no evidence of transmission; ?: questionable or unknown
9
Most viral transmissions associated to plasma products took place prior to the introduction of efficient viral
inactivation or removal procedures
10
Transmitted by contact with animal blood but not reported by transfusion
11
Limited epidemiological surveys have not revealed transmission of SARS coronavirus by transfusion but
further confirmation may be needed
12
Investigational studies performed by plasma fractionators using spiked TSE agents indicate that several
purification steps used in the manufacture of some plasma products are likely to remove prion agents. These
data may not necessarily be extrapolated to clearance of the endogenous form of the TSE agent in human
blood.
14. Page 14
4.4. Strategies to ensure plasma products safety
A combination of measures to exclude infectious donations, together with steps to
inactivate or remove potential contaminating viruses during processing, has significantly reduced
the risk of disease transmission by plasma products.
There are four distinct complementary approaches to virus risk reduction for plasma products:
• Minimizing the virus content of the plasma pool by :
implementing a quality system to select donors,
screening blood/plasma donations,
performing plasma manufacturing pool testing .
• Inactivating and removing residual viruses during plasma fractionation and
processing [3]
• Adherence to GMP at all steps of the production
• Recognizing and responding appropriately to post-donation events affecting plasma
donations that have already been processed
In-process and finished product virus inactivation and/or removal procedures have been
shown to play a powerful role in ensuring the viral safety of plasma products, in particular from
HIV, HBV, and HCV risks [3, 11]. Those procedures were also recently shown to provide a
sufficient margin of safety against emerging lipid-enveloped viruses, like WNV [[9, 10]].
Although viral inactivation and removal treatments may therefore seem to offer the
fractionator an ideal means to totally counter-balance occasional lapses in identification of risk
donations, such an assumption would be incorrect. As powerful as the contribution of properly
validated and implemented virus inactivation/removal steps has been shown to be, it remains
essential to limit the virus load at the stage of the plasma pool by avoiding, through donor selection
and donation screenings, the inclusion of a high-titre infectious donation. The synergistic effects of
reduced viral load in the plasma pool and validated viral inactivation and removal procedures are
well illustrated for resistant non-enveloped viruses, like parvovirus B19, where viral reduction
procedures used during fractionation alone may not be sufficient to ensure safety [12, 13].
Exclusion of infectious donations, and retrospective identification of any infectious
donation that would have passed through the screening and testing net, require the highest priority
at the blood establishment. The blood establishment should establish a reliable mechanism to
ensure consistent identification of those donations.
Neither set of the measures listed above can, in isolation, provides sufficient assurance of
safety against all potential blood-born pathogens. For this reason, the manufacture of plasma for
fractionation according to Good Manufacturing Practices (GMP) is necessary in order to ensure the
optimal quality and margin of safety of this raw material for the manufacture of medicinal plasma
products.
15. Page 15
4 MEASURES TO EXCLUDE INFECTIOUS DONATIONS
The safety and quality of plasma for fractionation results from the combination of several
cumulative prevention measures
1. Appropriate selection of blood/plasma donors
2. Testing of blood/plasma donations
3. Epidemiological surveillance of the donor population
4. Strict adherence to Good Manufacturing Practices (GMP)
5. Post-donation information system
Such information on collection and testing of plasma is requested by some regulatory
authorities as part of a plasma master file [14] used in the evaluation of the marketing authorization
of plasma-derived medicinal products.13
4.1 Appropriate selection of blood/plasma donors
Plasma for fractionation should be obtained from carefully selected, healthy donors who,
after review of the medical history (the donor questionnaire), medical examination, and laboratory
blood tests, would be considered not to present an increased risk for transmission of infectious
agents by plasma-derived products (see Annex 2). Local NRAs are pivotal in setting up at the
national level an harmonized donor selection criteria framework appropriate to the country of
plasma collection, taking into account the type of products, the relevant infectious risks, and the
epidemiological situation. The local NRA should also be part of any decision making process
intended to modify the donor selection and donation testing procedures. Specific selection criteria
may be added by the plasma fractionator as part of the contractual agreement with the provider of
plasma.
Regulatory agencies and a number of organizations, respectively, have published
regulations and recommendations concerning the criteria for the selection of donors of whole blood
and of plasma obtained by apheresis (see for instance “Guide to the preparation, use and quality
assurance of blood components” of the Council of Europe [15], which is regularly updated). In
general these regulations and recommendations can be used as reference for the collection of
plasma for fractionation, although some specifications may differ from those of plasma for
transfusion. Examples of donor selection criteria for the collection of plasma for fractionation are
presented in Annex 3. These are not intended to constitute an absolute reference or requirements,
but rather to provide examples and explain critical points for consideration.
A regular donor is someone who routinely donates blood or plasma14 in the same centre in
accordance with the minimum time intervals. A repeat donor is someone who has donated before
in the same establishment but not within the period of time considered as regular donation. Plasma
fractionators may implement their own criteria of donors’ eligibility to improve safety margins.
Whenever possible, plasma for fractionation should be collected through a donation system
involving regular and repeat donors. Obtaining plasma from regular and repeat donors plays a
13
The plasma master file is not a universally used regulatory document
14
The period taken into account may vary from country to country
16. Page 16
major contribution to ensure optimal historical medical information about the donors, and therefore
for detecting potential risk factors.
In some countries family or replacement donors may constitute a significant proportion of
the population of blood plasma donors, and - depending upon situations - have been found [16] or
not [17] to be at higher risks than regular/repeat donors to have markers of viral infections. The
decision to use this plasma for fractionation is to be made jointly by the plasma fractionator and the
NRAs and should be based on both a careful epidemiologic assessment and the evaluation of other
safety measures in place for viral screening of donations.
Plasma may be collected by plasmapheresis from donors who have acquired immunity
through natural infection or through active immunization. Specific information on this item can be
found under Annex 3.
4.2 Screening of blood/plasma donations for infectious markers
4.2.1 Screening tests
The following tests, considered mandatory by all regulatory agencies, are relevant to the
preparation of plasma for fractionation and should be performed at each blood/plasma donation:
o an approved test for HBsAg;
o an approved test for anti-HIV;
o an approved test for anti-HCV.
All three tests should be negative.15 Initially reactive donations should be retested in
duplicate by the same assay. A repeatedly reactive donation should not be used for therapeutic
applications and should usually be destroyed16. A sample of the donation should be evaluated by a
confirmatory test and if confirmation is positive a system should exist to notify and counsel the
donor. It is recommended that national algorithms should be developed and used to enable
consistent resolution of discordant or unconfirmed results.
4.2.2 Other tests
The screening of plasma for fractionation for anti-HTLV is not required as the virus is cell-
associated and susceptible to freeze-thaw process.
In some countries, testing for anti-HBc is performed on whole blood donations as a means
to reduce the exposure risks to hepatitis B positive blood components donations [18]. However,
plasma for fractionation donations obtained from whole blood that are both anti-HBc positive and
HBsAg negative, and which contains a sufficient titer in antibodies against hepatitis B surface
antigen (anti-HBs) are usually used for fractionation: the scientific rationale is to maintain a
sufficient anti-HBs antibody titre in the plasma pool to neutralize any HBV that may be present.
The minimum anti-HBs titer for an anti-HBc positive/HBsAg negative plasma donation to be
15
Testing for HIVP24 and HCV core antigens may increase the sensitivity
16
Unless useful for non-therapeutic use or investigations
17. Page 17
accepted for fractionation may be specified by the plasma fractionator and/or the NRA17.
Alternatively, the plasma donation may be identified by the plasma collector as being anti-HBc
positive and the plasma fractionator may conduct additional testing. The setting of a minimum
limit, if any, in anti-HBs antibody titre usually involves a risk assessment, considering the
sensitivity of the HBsAg screening test, the testing or not of HBV by NAT, and the efficiency of
the viral reduction techniques [3, 19].
Additional testing for other agents or markers may be required by the NRA, taking into
consideration the epidemiological situation in any given area or country, or the frequency of
donating blood or plasma, and at the specific request of the plasma fractionator.
4.2.3 NAT testing
NAT testing of plasma for fractionation may be performed for the following viruses: HCV,
HBV, HIV, HAV, and/or B19. If NAT testing is performed by the fractionator, following current
practice using mini-pool samples, a specific logistics system may have to be developed at the blood
establishments to collect and provide labelled samples in a form suitable for the test.18
4.2.4 Test kits
A system should exist in the country or region for approval of tests kits, such as an official
approval system by the National Regulatory Agency or a delegated laboratory. The required
sensitivity of the tests for the different antigens/antibodies should be determined by the NRA. In
addition, the test kits used should be agreed by the fractionator that will receive the plasma for
fractionation.
4.2.5 Quality control of screening
The quality of the screening of blood/plasma donations relies on a number of measures,
such as:
o validation of new techniques before implementation;
o internal control of reagents and techniques on a daily basis;
o confirmation of positive tests by an appropriate laboratory;
o external proficiency testing which involves the testing of a panel of sera circulated
to laboratories by an approved reference institution.
Details on sampling, test equipment, assays performance validation, test interpretation and
downloading and follow-up of reactives can be found under QA and GMP in this guideline.
4.2.6 Look- back
A system should be in place to perform a look- back procedure, preferably using a
computer data base. A look-back is a procedure to be followed if it was found retrospectively that a
17
Currently, the minimum titer in anti-HBs antibodies usually required by some plasma fractionators ranges
from 50 to 100 IU/L
18
In addition to performing mini-pool testing, fractionators re-test the plasma manufacturing pool for the
absence of various viral markers
18. Page 18
donation from a donor should have been excluded from processing, e.g. because that unit was
collected from a donor that subsequently has been rejected for reactive viral marker, risk
behaviour, exposure to CJD/vCJD or other risks related to infectious diseases. The blood
establishment should then transmit this information to the fractionator according to their
agreements in place, and to the NRA. Donor notification and counselling is recommended both for
purposes of donor health and for the safety of the blood supply
4.3 Epidemiological surveillance of donor population
To ensure optimal long-term safety of plasma for fractionation, it is highly recommended to
establish a continuous epidemiological surveillance of the donor population19. The objective of this
survey is to know, as precisely as possible, the prevalence and incidence, and their respective
trends, of infectious markers that are relevant to the safety of medicinal plasma products so that
counter-measures can be made in a timely fashion..
The system should be able to gather epidemiological data at the national/regional level but
also among donor populations which are providing blood/plasma for fractionation at individual
blood establishments within a country or a region.
The information from the epidemiological surveillance can furthermore be used:
a. to detect differences among donor populations of various collection centres which may be
associated with objective differences in viral markers within donor populations or may
reflect differences in the donor selection and screening process among collection centres;
b. to detect trends in infectious markers which may reflect either a change in the rate of viral
markers in the population or a possible deviation in the donor selection or screening process
at specific collection sites;
c. to assess the relevance of any prevention measures such as a strengthened donor selection
process, additional exclusion criteria, or implementation of additional screening tests to
avoid contamination of plasma products.
When donations from first time donors are used to prepare plasma for fractionation20,
epidemiological data of this specific donor group should be included in the estimation of the risk
for infectious diseases transmitted by blood. Indeed, it has been shown that first-time donors, who
may occasionally include test-seeking individuals, constitute a group which in some situations is
more likely to have blood-borne viral markers than regular donors group who have already gone
through a selection/deferral process [20-23].
Currently, it is advisable to collect and analyse epidemiological data at the collection sites
for anti-HIV 1 / 2, anti-HCV, and HBsAg, since they historically represent the major pathogenic
risks associated to plasma products. It is the responsibility of the local NRA to define whether the
list should be modified or should include additional criteria, such as emerging infectious agents,
based on local or regional epidemiology. For the current three recommended markers, only
19
This is not a requirement in all regions of the world
20
Some plasma fractionators do not fractionate plasma from first-time donors as prevalence of infectious
diseases may be higher in this donor group.
19. Page 19
confirmed positive tests (i.e. tests which are repeatedly reactive in a screening test and positive in
at least one confirmatory test) should be recorded.21
A recent guideline published by the European Medicines Agency (EMEA) entitled
"Guideline on epidemiological data on blood transmissible infections"[24] describes how to
conduct epidemiological surveillance of the donor population.
4.4 Strict adherence to Good Manufacturing Practices
Because of the pooling of thousands of plasma donations is required for the manufacture of
plasma derived medicinal products, it is necessary to ensure full traceability between individual
blood/plasma units collected and the final plasma products manufactured. This is of importance to
be able to trace back any quality and safety problems, in particular related to infectious risks, to
individual blood/plasma donations and to take relevant measures to protect the donors as well as
the patients who received the plasma derived medicinal products.
The donor selection process, the collection of blood/plasma and the processing of the
donation, in order to obtain plasma for fractionation, represent the first steps in the manufacturing
of plasma derived medicinal products, and therefore should be performed in compliance with
GMP. Strict adherence to GMP principles and the implementation of a quality assurance system to
address and comply with GMP requirements is crucial at all stages of the production of plasma for
fractionation. See chapter on QA and GMP in this Guideline.
4.5 Post donation events
There should be a system to ensure effective communication between the blood
establishment and the fractionator so that significant post-donation events may be immediately
transmitted to the fractionator and the NRA. In particular, this procedure should allow early and
effective communication of any evidence for the presence of blood-transmissible infection in a
donor whose plasma was sent for fractionation.
5 PRODUCTION OF PLASMA FOR FRACTIONATION
5.1 Methods used to obtain plasma for fractionation
Technically, human plasma for fractionation may be obtained by separation of plasma from
whole blood, or by apheresis.
5.1.1 Recovered plasma
Recovered plasma is plasma recovered by centrifugal separation from the cells and cellular
debris of whole blood, following conditions described later.
21
when the plasma fractionator performs additional tests (such as NAT tests) on donations which tested
negative by serological tests, the results should be reported.
20. Page 20
5.1.2 Apheresis plasma (source plasma)
Apheresis Plasma obtained by a procedure in which anticoagulated blood is removed from
the donor, the plasma is separated from the formed elements, and at minimum the red cells are
returned to the donor. The separation of cellular elements and plasma may be achieved either by
centrifugation or filtration. The equipment used for the collection of plasma by automated methods
is designed for such use. The manufacturers of the equipment provide operating manuals that
include instructions for installation validation, routine preventive maintenance procedures, periodic
performance checks (e.g., weight scale checks), alert mechanisms (e.g., haemoglobin detector) and
troubleshooting. Annual preventive maintenance should be performed by a qualified field service
Engineer.22 Additionally, the manufacturers of the equipment usually provide support for the
installation and train on-site technicians to maintain the equipment. Apheresis collection potentially
increases the availability of plasma for fractionation, enabling higher donation frequency and larger
volume per donation, independently from the collection of whole blood, and is the preferred
approach for the regular collection of plasma from hyperimmune donors who have high antibody
titres against specific disorders.
In principle, the method of preparation should remove cells and cell debris as completely as
possible and should be designed to prevent the introduction of micro-organisms. No antibacterial or
antifungal agent is added to the plasma. The residual blood cell content of the plasma, in the
absence of dedicated leucoreduction filtration, may vary with the collection method.
5.2 Characteristics of plasma for fractionation
5.2.1 Plasma frozen within 24 hours of collection
Subject to appropriate handling (storage and transport), plasma frozen, at -20°C or -30°C,
within 24 hours of blood collection or apheresis (see § 6.6.2.1) will normally be suitable for
optimal recovery of both labile factors (factor VIII and other coagulation factors and inhibitors)
and stable plasma proteins (usually albumin and immunoglobulins)23. Table 4 sets out the main
characteristics of plasma prepared either from whole blood (recovered plasma) or by apheresis.
Both sources of plasma have been found by experience to be appropriate for the
manufacture of the whole range of plasma products. That said, the method of collection and
preparation has some impact on the characteristics and/or yield of the proteins fractionated from
the plasma. Apheresis plasma collected from donors undergoing frequent plasmapheresis contains
lower levels of IgG than plasma units produced by moderate serial plasmapheresis or from whole
blood [25, 26]. The content of various coagulation factors is usually higher in apheresis plasma
compared to recovered plasma [26, 27], due to a combination of reasons that include rapid
separation of blood cells and plasma, differing ratios of anticoagulant added, and the possibility of
freezing the plasma soon after completion of collection.
22
It includes e.g. visual inspection, initial operational integrity, equipment integrity inspection, filter and/or
centrifuge inspection, calibration testing, and safety testing.
23
Plasma meeting these quality specifications is also used for direct clinical applications; it is then referred
to as fresh frozen plasma (FFP), clinical plasma, or plasma for transfusion
21. Page 21
Table 4: Characteristics of plasma for fractionation used in the manufacture of labile plasma
products
Characteristic Recovered plasma Apheresis plasma
Volume, ml 100-26024 450-88025
≥50 [15]
Protein content, g/l ≥50
(each donation) (but typically greater than in apheresis plasma)
Factor VIII, iu/ml ≥0.7 [28] ≥0.7
(average) (but typically less than in apheresis plasma)
Anticoagulant Variable, according to donation size (volume of Constant (metered
concentration anticoagulant is fixed for a given pack type; the into donation)
acceptable blood volume range should be
specified)
Acceptable Determined nationally, usually subject to a Determined
donation frequency maximum of one donation every 2 months nationally
Preservation of factor VIII and other labile factors depends on the collection procedure and
on the subsequent handling of the blood and plasma. With good practice, an average of 0.7 IU/ml
factor VIII can usually be achieved both with apheresis and recovered plasma. Units of plasma for
fractionation with a lower activity may still be suitable for use in the production of coagulation
factor concentrates, although the final product yield may be reduced.
The implementation of good manufacturing practices in the preparation of plasma for
fractionation should ensure that plasma bioburden is controlled, labile proteins are conserved as far
as possible, and minimal proteolytic activity is generated.
5.2.2 Plasma frozen after 24 hours of collection
Plasma may be available that does not fulfil the above-defined criteria but still has value as
a source of some plasma proteins. This would include:
Plasma separated from whole blood and frozen more than 24h but usually less than 72hrs
after collection
Plasma, separated from whole blood stored at 4°C, and frozen within 72 hrs of separation
but within the assigned shelf-life of the blood)
Plasma frozen within 24 hours but stored under conditions that preclude its use for the
manufacture of coagulation factors.
Provided the circumstances of manufacture and storage of such plasma does not result in
increased bioburden, the plasma may be considered suitable for the manufacture of stable plasma
proteins, but not coagulation factors.
24
Based on a standard donation size of 450ml, with blood:anticoagulant ratio of 7:1. The maximum volume
of blood to be collected during one donation procedure is determined by national authorities
25
With anticoagulant. The maximum volume of plasma to be removed during one plasmapheresis procedure
is determined by national authorities
22. Page 22
Plasma which is not frozen with 72 hrs of collection or separation from whole blood should
not be used for fractionation.
5.2.3 Plasma not meeting the requirement for fractionation
Plasma obtained by therapeutic plasma exchange does not meet the criteria for fractionation
to plasma products. Indeed, plasma from individuals subjected to therapeutic plasma exchange for
the treatment of a disease state may present an enhanced risk of transmitting blood-borne diseases
(due to infectious risks associated to plasma) and a high risk of irregular antibodies, and should not
be offered for fractionation. In addition, such plasma cannot be classified as being obtained from a
voluntary donor.
Plasma from autologous blood donations is excluded from use as plasma for fractionation
and may have higher prevalence of viral markers [29].
5.2.4 Hyper-immune (antibody-specific) plasma
Detailed information regarding immunization of donors for the preparation of hyperimmune
plasma is provided in Annex 3. The following are the three approaches for the preparation of
plasma for the manufacture of specific immunoglobulins (antibody-specific immunoglobulins):
Individuals selected from the normal population by screening of plasmas units for antibody
titres. (Screening may be random, or may be informed by knowledge of history of recovery
from an infectious disease – for example varicella)
Individuals with a high titre of a specific antibody resulting from prophylactic
immunization.
Volunteers recruited to a panel for a targeted immunization programme. The clinical and
ethical requirements for such a programme are considered in Annex 3.
Clinically relevant antibody specific immunoglobulins include anti-D (anti-Rho), and anti-
HAV, anti-HBs, anti-tetanus, anti-varicella/herpes zoster and anti-rabies immunoglobulins. For the
most part, hyperimmune globulins are prepared for intramuscular administration, but products for
intravenous use are also available. The typical derivation of hyperimmune plasma of each
specificity is summarized in Table 5.
23. Page 23
Table 5: Types of hyperimmune plasma
Specificity Natural Immunity Prophylactic Targeted
Immunization Immunization
Anti-D (anti-Rho) Yes No Yes
Anti-hepatitis A (anti- Yes Yes Yes
HAV)
Anti-hepatitis B (anti- Yes Yes Yes
HBs)
Anti-tetanus No Yes Yes
Anti-varicella/herpes Yes No Possibly
zoster
Anti-cytomegalovirus Yes No No
(anti-CMV)
Anti-rabies No Yes Yes
Acceptable minimum antibody potencies in individual plasma donations for fractionation
should be agreed to by the fractionator. Those usually will depend upon (a) the size and
composition of the fractionation pool (which may include high-titer donations to increase the mean
titer of the fractionation pool), (b) the characteristics of the immunoglobulin fractionation process,
and (c) the minimum approved potency of the final IgG product.
The following general guidance may be useful for each specificity:
5.2.4.1 Anti-D (anti-Rho)
• Antibody potency should be estimated in international units, using an appropriate
quantitative assay (e.g. autoanalyser-based assay or flow cytometry method) agreed
to by the fractionator.
5.2.4.2 Anti-HAV
• Antibody potency should be estimated in international units, using a quantitative
assay agreed to by the fractionator.
• The minimum acceptable potency in individual donation is unlikely to be less than
50 iu/ml.
5.2.4.3 Anti-HBs
• Antibody potency should be estimated in international units, using a quantitative
assay that detects antibody to hepatitis B surface antigen (typically RIA or ELISA)
agreed to by the fractionator.
• The minimum acceptable potency in individual donation is unlikely to be less than
10 iu/ml.
24. Page 24
5.2.4.4 Anti-tetanus
• Antibody potency should be estimated using either a neutralization assay or a
quantitative assay with established correlation to the neutralization assay, agreed to by
the fractionator.
5.2.4.5 Anti-varicella/zoster
• Antibody potency should be estimated using a quantitative assay (typically ELISA,
immunofluorescence or complement fixation) agreed to by the fractionator.
• The minimum potency should be shown to be equal to or greater than that of a
control sample provided by the fractionator.
5.2.4.6 Anti-cytomegalovirus
• Antibody potency should be estimated using a quantitative assay (typically ELISA,
immunofluorescence or complement fixation) agreed to by the fractionator.
• The minimum potency should be shown to be equal to or greater than that of a
control sample provided by the fractionator.
5.2.4.7 Anti-rabies
• Assessing plasma for rabies antibody is rarely done. A donor may be considered to
have acceptable antibody titres between 1 and 3 months after a second (or booster)
dose of vaccine. Plasma should not be collected from persons immunized after
exposure to infection by rabies virus.
5.3 Premises and devices for collection of plasma for fractionation
5.3.1 Premises
The collection of blood/plasma for fractionation should be performed in licensed, or
regulated, permanent premises or mobile sites which are compliant with the intended activity and
comply with the GMP standards approved by the NRA. The area for blood donors should be
separated from all processing and storage areas. The area for donor selection should allow
confidential personal interviews with due regard for donor and personnel safety. Before premises
are accepted for mobile donor sessions, their suitability should be assessed against the following
criteria.
• the size to allow proper operation and ensure donor privacy,
• safety for staff and donors, and
• adequate ventilation, electrical supply, lighting, hand washing facilities, blood storage and
transport equipment, and reliable communication capabilities.
5.3.2 Containers
Because plasma is a complex and variable mix of proteins in aqueous solution, the way in
which it is handled will have consequences for its safety, quality and quantity. Furthermore, the
effects of mishandling will not always be as simple (or as obvious) as reducing the content of
25. Page 25
recoverable factor VIII – they are just as likely to impact on the behaviour of the plasma when it is
thawed (this is very important to the fractionator, who requires consistency from this particularly
important process step).
The containers used for the collection and storage of plasma for fractionation should
comply with the appropriate regulatory provisions and should be under the control of the regulatory
authority. Containers should also comply with the regulatory and technical requirements of the
plasma fractionator. Containers should be labelled with batch numbers traceable to individual
donations. The quality of containers has a direct impact on the quality of the plasma produced and
it is therefore part of GMP to control the suitability of this starting material before use.
Containers of whole blood collections are the same for donations of whole blood from
which plasma is used for fractionation. They should be plastic, and should have been
manufactured in such a way as to give assurance of internal sterility; they should be hermetically
sealed to exclude contamination. If the container is not manufactured as an integral part of a blood
collection set, there should be a mechanism for docking with the collection set that minimizes the
risk of adventitious microbial contamination.
Validation studies will be required to confirm the suitability of the container material (and
the material of any tubing or harness through which plasma should pass) during storage in contact
with the plasma. Specifically, it will be necessary to establish that the plastic is physically
compatible with the proposed methods for freezing and opening (or thawing) the packs and to
establish the quantities of extractable materials (for example, plasticizers) during the claimed
periods of liquid and frozen storage. These studies are carried out by the manufacturer of the
containers. When using collection sets and containers previously established by a manufacturer as
being suitable, a cross-reference to such a study may be sufficient. Validated blood/plasma
collection and storage containers are available from several manufacturers worldwide.
The choice of the containers (e.g. type of plastic bags for recovered plasma or plastic bags
or bottles for apheresis collection) has a direct impact on the design of the container opening
machine that is used at the plasma fractionation plant at the plasma pooling stage.
Anticoagulant solutions should comply with the appropriate regulatory provisions. They
can be already present in the collection container (e.g. plastic containers used for whole blood
collection) or added to the blood flow during apheresis procedures. For both, the device and the
anticoagulant information should be provided to the regulatory authorities. The fractionator will
need to know what anticoagulant was used, and its concentration as they may have an impact on
the fractionation process.
5.3.3 Anticoagulants
Most anticoagulant solutions developed and introduced for the collection of blood cellular
components and plasma for transfusion are compatible with the preparation of plasma for
fractionation and with the manufacture of plasma products (although some influence on factor VIII
content in plasma has been described [30-34]). One exception is when heparin is added to the
anticoagulant solution. Main anticoagulant solutions currently in use for collection of either whole
blood or apheresis plasma are listed in Table 6.
27. Page 27
5.4 Blood/plasma collection process
5.4.1 Procedure
A standardized and validated procedure for the preparation of the phlebotomy site should
be followed using a suitable antiseptic solution, and allowed to dry depending on the type of
disinfectant. The prepared area should not be touched before needle has been inserted. Prior to
venipuncture the containers should be inspected for defects. Any abnormal moisture or
discolouration suggests a defect. Careful check of the identity of the donor should be performed
immediately before venipuncture.
The collection of a whole blood unit used to prepare plasma for fractionation should be
performed following already established recommendations (for instance as described in the
Council of Europe Guide [15]). In particular, good mixing of the blood with the anticoagulant
solution should be ensured as soon as the collection process starts to avoid risks of activation of the
coagulation cascade. The mixing can be done manually, every 30 to 45 seconds, at least every 90
seconds. Collection of one standard unit of blood should be achieved within 15 minutes, as longer
durations may result in activation of the coagulation factors and cellular components.
In automated procedures, whole blood is collected from the donor, mixed with
anticoagulant, and passed through an automated cell separator. The plasma for fractionation is
separated from the cellular components of the blood, which are returned to the donor in a series of
collection/separation and return cycles. The plasma is separated from the red blood cells by
centrifugation or filtration, or a combination of both [35, 36]. The operational parameters of the
plasmapheresis equipment are defined by the manufacturers of the equipment and by requirements
of NRAs. In general, the anticoagulant (often 4% sodium citrate) is delivered at a rate to yield a
specified ratio of anticoagulant to blood. The volume of plasma collected from the donor during
one procedure and over a period of time is regulated. The number of collection/separation and
return cycles for each donor depends on the total volume of plasma that is to be harvested. For
determining the number of cycles employed, the equipment requires programming by data inputs.
These data elements may include such parameters as donor weight and hematocrit values. The
amount of time required for the donation procedure depends on the number of cycles (and hence
the volume of plasma collected) but generally falls between 35 – 70 minutes.
5.4.2 Labelling of collection bags
There should be a secure system for procurement, printing and storing of the barcode labels
used to identify the main collection bags and the satellite bags, associated samples and
documentation in order to ensure full traceability at each stage of plasma production. There should
be a defined procedure for labelling collection bags and samples – in particular the procedure
should ensure that the labels correctly identify the association between samples and donations.
This should be performed in a secure manner, e.g. at the donor couch, prior to collection, or
immediately after the start of collection, to avoid mislabeling. Duplicate number sets of barcode
donation numbers should not be used. Information on the label of the donation should include:
official name of the product; volume or weight; unique donor identification; name of the blood
28. Page 28
establishment; shelf life or shelf term; shelf temperature; and name, content and volume of
anticoagulant
5.4.3 Equipment
Equipment used for the collection and further separation of blood should be maintained and
calibrated regularly, and the collection and separation process needs to be validated. When
validating the quality of the recovered plasma, a set of quality control tests, including measurement
of total proteins, residual blood cells, haemoglobin, and relevant coagulation factors, such as Factor
VIII, should be included. In addition, markers of activation of the coagulation and fibrinolytic
systems may, if necessary, be performed with the support of the plasma fractionator [37] based on
the specifications of the plasma for fractionation set out by the fractionator and/or the NRA.
Likewise, apheresis equipment and apheresis procedures should be validated, maintained and
serviced. Validation criteria with regards to the quality of plasma for fractionation also include
protein recovery, residual content of blood cell and haemoglobin, and relevant coagulation factors.
Validation studies of new apheresis procedures should also evaluate possible risks of activation of
the coagulation, fibrinolysis, and complement systems potentially induced by the material in
contact with blood [27, 37-39]; such studies are usually performed by the manufacturer of the
apheresis machines.
5.4.4 Laboratory samples
Laboratory samples should be taken at the time of blood/plasma collection. Procedures
should be designed to avoid any mix-up of samples and samples awaiting testing should be stored
at an appropriate temperature, as specified in the operating instructions of the test kits.
5.4.5 Volume of plasma per unit
The volume of recovered plasma per container varies depending upon the volume of whole
blood collected, the respective hematocrit of the donor, and the volume of the anticoagulant
solution. The volume of apheresis plasma per container depends directly upon the volume
collected during the apheresis session and the volume of anticoagulant. The range of volume of
blood and plasma collected per donor is usually defined in national regulations taking into
consideration criteria such as the weight of the donor.
Although the collection of whole blood is in most countries close to 400-450 ml per donor,
in some it may be as low as 200 ml (under those circumstances, the volume of anticoagulant
solution is reduced so that the plasma/anticoagulant ratio is constant). As a result the volume of
recovered plasma per unit (including anticoagulant) may vary from about 100 to 260 ml per
container. In the case of plasmapheresis plasma, the volume may range from about 450 to 880 ml
per container, depending upon the country’s regulations.
The volume of plasma per container has direct practical impact on the fractionation process
and manufacture of plasma products. Small volume donations (e.g. 100 ml) will require more
handling by the plasma fractionation operators at the stage of plasma preparation, container
opening step, and plasma thawing. The overall container opening process will take longer,
29. Page 29
requiring additional care to control bacterial contamination. Another consequence is that the
number of donations contributing to a plasma pool will be higher (for instance, 20'000 plasma
donations for a pool size of 2000 litres).
5.4.6 Secure holding and reconciliation
When the collection process is finished, it should be ensured that blood/plasma donations
are held at the donation site using a secure system to avoid mishandling.
Prior to dispatching the collected donations to the blood/plasma processing site,
reconciliation of the collected donations should be performed according to a standardized
procedure. The procedure should also specify the actions needed in case there are missing numbers
and leaking containers. Documentation should accompany the donations to the plasma processing
site, to account for all donations in the consignment.
5.4.7 Donor call back system
A system should be in place in the blood establishment which allows recall of a donor if
further analysis or investigation is necessary.
5.5 Separation of plasma
5.5.1 Premises
Blood processing should be carried out in adequate facilities compliant with the intended
activity. Donor area and plasma processing areas should be separated from each other whenever
possible. Each area of processing and storage should be secured against the entry or intervention of
unauthorised persons and should be used only for the intended purpose. Laboratory areas and
plasma storage areas should be both separated from the donor and processing areas.
5.5.2 Intermediate storage and transport
Transport of the donations and samples to the processing site should be done according to
procedures that ensure both constant approved temperature and secure confinement. This is
especially important when blood/plasma is transported from distant blood drive sessions.
Temperature monitoring is important to ensure optimal compliance and quality. One way is by
ensuring packaging methods that can keep the blood/plasma within the required temperature limits.
One approach to record temperature is to put portable temperature loggers for monitoring the
transportation of blood/plasma to the processing site.
5.5.3 Impact of whole blood holding period
It has been shown that whole blood anticoagulated with CPD, transported and stored at
22°C for up to 8 hrs prior to separation of plasma is suitable for the production of plasma for
fractionation but factor VIII activity is reduced by an additional 15 to 20 percent if blood is stored
30. Page 30
for 24hrs [40]. Rapid cooling of whole blood to 22°C +/- 2°C immediately after collection (using
e.g. cooling units with butane-1,4-diol) [41] protects factor VIII and may allow storage of blood for
24 h [42]. 4°C transportation/storage of blood collected with either ACD, ACD-adenine, or CPD
anticoagulants consistently appears to reduce the FVIII content, but not necessarily that of other
proteins, especially after 8 hrs of holding time [43-46]. Holding blood at 4°C for a period of time
over 8hrs is therefore not recommended when plasma is used for fractionation in the manufacture
of factor VIII products.
5.5.4 Centrifugation of whole blood
Blood and plasma collection documentation should be checked at the processing laboratory
at receipt of the donations; reconciliation between consignment and documentation received should
be performed. Blood separation procedures should be performed using a closed system and should
be validated, documented and proven to ensure that container identification is correct.
Reproducible production characteristics of the plasma for fractionation, following a validated
procedure, should ensure consistency in the residual blood cell count and protein content and
quality to meet the specifications set out by the blood establishment or the NRA and the plasma
fractionator are met.
It has been shown that CPD whole blood units that were centrifuged under conditions of
low g force for a long time as compared to high g force for a short time yielded blood components
of similar quality [47]. Blood separation classically starts with the isolation of the platelet-rich
plasma (PRP) fraction from whole blood by low-speed centrifugation. Subsequent high-speed
centrifugation of PRP in turn yields the corresponding platelet concentrate and the plasma.
Blood processing methods that include removal of the buffy-coat layer have gradually
shifted from manual extraction procedures to fully automated systems. This allows standardized
extraction and contributes to GMP in the preparation of blood components including plasma for
fractionation [48]. Blood component separation systems may be based on buffy coat extraction via
the Top & Bottom technique [49]. Its efficacy in terms of yield, purity, and standardization of blood
components has been well established.
Several technical approaches have been developed to separate blood components. The
process may involve normal centrifugation to separate the blood components, which are
subsequently squeezed out from the top and bottom simultaneously under control of a photocell.
This primary separation step results in three components: a leukocyte-poor red-cell suspension,
plasma, and a buffy-coat preparation [49]. Multiple bag system with top and bottom drainage of the
primary bag allows automatic separation of blood components; plasma containing 14.6 +/- 5.6 x
103 platelets /µl and 0.04 +/- 0.035.6 x 103 leucocytes /µl is obtained [50]. Blood components may
be separated by initial high-speed centrifugation (4,158 g, 14 min, 22ºC) of whole blood in sealed
triple or quadruple bag systems, followed by simultaneous extraction of fresh plasma at the top,
and the red blood cell concentrate at the bottom, of the respective satellite bags that constitute the
blood extraction bag system – keeping the leukocyte-platelet buffy coat layer stable throughout the
process within the original extraction bag. The buffy coat component yields the platelet concentrate
after low-speed centrifugation and removal of the plasma from the PRP. Automatic separators that
subsequently express the various components into their respective satellite bags in top and bottom
systems yields plasma containing 3+/-3 x 106 leucocytes and 4+/-3 x 109 platelets per unit [51].
31. Page 31
The Top & Bottom approach allows a marked reduction in leukocyte contamination of the different
blood components [41, 52], and may yield optimal plasma volume [41].
5.5.5 Impact of leucoreduction
Recently, several countries have implemented universal leucoreduction of the blood supply
[53, 54] to avoid cell-mediated adverse events or improve viral safety of blood components. It has
also been considered as a precautionary measure against the risk of transmission of variant
Creutzfeldt-Jakob disease (vCJD). A recent study in an endogenous animal infectivity model
reports that leucoreduction of whole blood removes 42% of the vCJD infectivity associated with
plasma [55], whereas further investigation by the same group found a ~70% removal of
infectivity26. The impact of leucoreduction on plasma protein recovery and activation markers
appears dependent upon the chemical nature of the filters [56, 57]. Some loss of coagulation factors
and sometimes an increase in the markers of coagulation and complement activation have been
found although the impact on the quality of fractionated plasma derivatives is not known [57, 58].
Therefore, until more scientific data are gathered, the benefit of leucoreduction on the
quality and safety of plasma products remains debated. The decision to leuco-reduce plasma for
fractionation should be assessed with the plasma fractionator and the NRA.
5.6 Freezing of plasma
Freezing is an important processing step that has an impact on some aspects of the quality
of plasma for fractionation, in particular with regard to the content in Factor VIII.
Several aspects in the freezing conditions of plasma for fractionation have been evaluated
5.6.1 Holding time of plasma
Holding plasma, freshly harvested from CPD-whole blood, at ~ 4°C for up to 24hrs before
freezing at -20°C for 4 months was shown to induce close to 25% loss of FVIII activity compared
to plasma frozen immediately, whereas other coagulation factors were not affected [59]. Storing
plasma at 22°C for 2 to 4 hours does not seem to induce a significant loss of factor VIII activity;
However, after 4 hours, some loss of activity takes place [44, 60].
Therefore, placing recovered plasma in a freezer as soon as possible, or at least within 4
hours, after separation from cellular elements, would be favourable to the recovery of factor VIII.
Similarly apheresis plasma should be frozen as soon as possible upon completion of the collection
procedure.
5.6.2 Freezing rate and freezing temperature
26
Dr. Rohwer, unpublished data
32. Page 32
5.6.2.1 Freezing conditions
The regulatory requirements for the temperature at which plasma should be frozen follow
different patterns [61], and depend upon the type of proteins fractionated.
The fractionator may also wish to specify specific freezing conditions depending on the
intended use of the plasma.
The European Pharmacopoeia currently states that recovered or apheresis plasma for
fractionation to be used for labile protein manufacturing (e.g. production of Factor VIII
concentrate) should be frozen rapidly, within 24 hours of collection, at – 30 °C or colder[28],27 as
this temperature has long been claimed to ensure complete solidification [62], and to be needed for
optimal freezing [63]. Recovered plasma used to manufacture only stable plasma proteins (e.g.
albumin and immunoglobulins) should be frozen within 72 hours of collection at -20°C or colder
[28].
The US Code Federal Regulations specifies that plasma collected by apheresis and intended
as source material for further manufacturing should be stored at -20 °C or colder immediately after
collection.
The rate at which freezing proceeds is considered to be an important quality factor, again at
least when coagulation factors are intended to be produced [64, 65]. Rapid plasma freezing
prevents or reduces loss of factor VIII in frozen plasma either recovered or obtained by apheresis
[25, 66, 67], and slow freezing of plasma was shown to influence the purity and recovery of Factor
VIII in cryoprecipitate [64, 67-69]. An ice front velocity of 26 mm/hour during freezing was
recently shown to preserve FVIII:C in plasma better than 9 mm/hour or less [60].
Therefore, freezing plasma rapidly (typically less than 2 hrs, so as to ensure quick ice front
velocity) down to a core temperature of at least -20°C, and preferably colder, appears the best
technical approach for the preservation of labile proteins.
5.6.2.2 Impact of containers and equipment
In order to ensure optimal and consistent freezing and storage conditions, it is important to
use plasma standardized containers as freezing time would be influenced by container shape,
volume, and thickness [60, 67, 68].
Optimum conditions, used by some plasma collectors, to ensure reproducible freezing
consist in freezing “well separated” plasma packs in a stream of moving cold air at the lowest
temperature tolerable to the plastic of the pack (a so-called “blast freezer”), and then to store the
frozen packs “close-packed” in a storage freezer at the agreed upon storage temperature. Worst
case would be to place a large number of unfrozen plasma bags, close together, in a domestic (-18°
to -22°C) freezer, adding more plasma bags for freezing each day, and storing the plasma under
27
Freezing conditions are currently under debate and the wording used in the European Pharmacopeia
monograph may be revised
33. Page 33
these conditions for several months. With good practice at the time of loading (i.e. not placing too
many packs in at the same time and keep them separated), a walk-in freezer at suitable temperature
offers a workable compromise.
The plasma fractionator will have to specify to the plasma collector, with the approval of
the NRA, which precise freezing parameters to use.
5.6.2.3 Validation of the freezing process
Recovered plasma and apheresis plasma should be shown to be frozen in a consistent
manner at the required temperature. A system should be in place for ensuring that plasma is frozen
to the correct core temperature within the time limit agreed upon with the plasma fractionator,
keeping in mind that the freezing speed will be influenced by the type of plasma container as well
as by the volume of plasma [67]. Validation of the freezing process by recording the temperature of
plasma donations during a freezing process allows evaluating the freezing capacity of the
equipment. Validation studies should be available, and should demonstrate that the temperature of
a frozen pack reaches the proposed storage temperature following the specifications agreed upon
with the manufacturer.
As indicated above, the aim should be to achieve rapid freezing, and thereafter to minimize
temperature changes to the frozen plasma.
5.7 Storage of plasma
5.7.1 Storage conditions and validation
Plasma for fractionation should be stored at -20°C or colder.
A multicenter study showed no detectable storage-related changes in 3 pools of plasma (2
recovered CPD plasma and 1 apheresis plasma) that have been quick-frozen at -30°C, or colder,
and stored over a period of 36 months at -20°C, -25°C, -30°C, or -40°C. A 11% reduction in FIX
was found in one of the recovered plasma pool during storage at -20°C for 2 years [70]. The
authors concluded that plasma may be stored at – 20°C for 2 years, or at -25°C, -30°C, or -40°C for
3 years.
By keeping the average storage temperature of the frozen plasma as constant as possible, at
or below -20 °C, the original quality of the plasma is maintained, without impacting the
fractionation process, in particular the cryoprecipitation step [63, 64, 69].
The European Pharmacopoeia has a provision stating that if the temperature of the plasma
is between -20°C and -15°C for a maximum of 72 hours, or if it is above -15°C (but colder than -
5°C) in no more than one occurrence, the plasma can still be used for fractionation.
Therefore, maintaining a constant storage temperature of -20°C or colder is a recommended
approach to ensure a consistent and optimal plasma quality.